|Publication number||US7382984 B2|
|Application number||US 10/262,944|
|Publication date||Jun 3, 2008|
|Filing date||Oct 3, 2002|
|Priority date||Oct 3, 2002|
|Also published as||EP1563619A1, EP1563619B1, EP3211809A1, US7376358, US9559778, US20040067064, US20050008364, US20060078336, US20170078016, WO2004032385A1|
|Publication number||10262944, 262944, US 7382984 B2, US 7382984B2, US-B2-7382984, US7382984 B2, US7382984B2|
|Inventors||John McNicol, Kieran Parsons, Leo Strawczynski, Kim B. Roberts|
|Original Assignee||Nortel Networks Limited|
|Export Citation||BiBTeX, EndNote, RefMan|
|Patent Citations (46), Non-Patent Citations (33), Referenced by (47), Classifications (19), Legal Events (7)|
|External Links: USPTO, USPTO Assignment, Espacenet|
This is the first application filed for the present invention.
The present invention relates to optical communications systems, and in particular to electrical domain compensation of optical dispersion in an optical communications system.
Optical communications systems typically include a pair of network nodes connected by an optical waveguide (i.e., fiber) link. Within each network node, communications signals are converted into electrical signals for signal regeneration and/or routing, and converted into optical signals for transmission through an optical link to another node. The optical link between the network nodes is typically made up of multiple concatenated optical components, including one or more (and possibly 20 or more) optical fiber spans (e.g., of 40-150 km in length) interconnected by optical amplifiers.
The use of concatenated optical components within a link enables improved signal reach (that is, the distance that an optical signal can be conveyed before being reconverted into electrical form for regeneration). Thus, for example, optical signals are progressively attenuated as they propagate through a span, and amplified by an optical amplifier (e.g., an Erbium Doped Fiber Amplifier—EDFA) prior to being launched into the next span. However, signal degradation due to noise and dispersion effects increase as the signal propagates through the fiber. Consequently, noise and dispersion degradation become significant limiting factors of the maximum possible signal reach.
Dispersion, also known as Group Velocity Dispersion or Chromatic Dispersion, in single mode fibre at least, occurs as a result of two mechanisms:
For the purposes of the present invention, references to “dispersion” shall be understood to mean the sum total of group velocity dispersion effects.
Mathematically, first order dispersion is the derivative of the time delay of the optical path with respect to wavelength. The effect of dispersion is measured in picoseconds arrival time spread per nanometre ‘line width’ per kilometre length (ps nm−1 km−1). The magnitude of waveguide and material dispersions both vary with wavelength, and at some wavelengths the two effects act in opposite senses. The amount of dispersion present in a link can also vary with the temperature of the cable, and if the route is changed (e.g., using optical switches). Dispersion in optical fibre presents serious problems when using light sources whose spectrum is non-ideal, for example broad or multispectral-line, or when high data rates are required, e.g., over 2 GB/s.
For the purposes of analyzing the effects of dispersion, it is convenient to represent an optical communications system using the block diagram of
In general, the output signal y(t) represents a distorted version of the input data signal x(t). While it would be highly desirable for H(w)≈1, this is rarely the case. Accordingly, it is frequently necessary to utilize at least some form of compensation, so that the original input data signal x(t) can be detected within the distorted output signal y(t).
One commonly used method of addressing the problem of dispersion in high-bandwidth communications systems is by inserting one or more optical dispersion compensators 8, represented in
These problems can be alleviated by moving the compensation function to the terminal ends (e.g., the transmitter 2 and/or receiver 6) of the link. This technique typically involves “preprocessing” the input signal x(t) at the transmitter (Tx) end of the link 4 to improve dispersion tolerance, and/or processing the output signal y(t) detected at the receiver (Rx) end of the link to accurately detect the input signal x(t) within the distorted output signal y(t).
For example, high bandwidth traffic can be distributed over a larger number of lower-rate channels. The reduced bit-rate of each channel enhances the dispersion tolerance in proportion to the square of the reduction in the bit-rate. However, this approach is expensive, spectrally inefficient, and creates four wave mixing problems.
Dispersion tolerance can be increased by narrowing the spectrum of the transmitted optical signal. Various known techniques may be used for this purpose, such as multilevel coding. However, this requires expensive electronics and significantly reduces the noise tolerance of the communications system.
Subcarrier multiplexing, which involves transmitting a plurality of lower bit-rate signals over one optical carrier, is another known method of increasing dispersion tolerance. In this case, the dispersion tolerance obtained is equivalent to that of the lower bit-rate subcarrier. However this approach is not cost effective and does not have a good noise tolerance.
The optical spectrum occupied by a signal can be reduced by use of modulators with reduced chirp, such as a Mach-Zehnder modulator. The amount of chirp can even be tailored to optimize transmission over a particular moderate amount of dispersion. One variation of this technique is referred to as dispersion supported transmission, an example of which is discussed in EP-A-0643 497. In this case, dispersion produces an FM to AM conversion effect, which can facilitate bit detection and thereby extend transmission distance without controlling or compensating dispersion. The dispersion causes shifting of adjacent signal components of different wavelengths, resulting in either energy voids or energy overlaps at the bit transitions. Constructive interference in an overlap causes a positive peak in the optical signal, while a void produces a negative peak. In principle, these positive and negative peaks represent an AM signal which may be detected to reproduce the original bit stream. This has proved difficult to implement over a reasonable range of practical link dispersions.
Many transmission formats are known that enable somewhat increased dispersion tolerance, for example, as described in U.S. Pat. No. 5,892,858. However none of these formats provide sufficient dispersion tolerance to allow a wide bandwidth signal to be accurately detected in the presence of large amounts of dispersion.
It is known that the use of a coherent receiver enables the signal degradation due to dispersion to be removed via linear electrical filtering. However, because of their high cost, very few coherent optical receivers have been installed, and the cost of replacing installed receivers with the high-performance coherent receivers is prohibitive.
The majority of receivers installed in modern optical communications networks are of the direct detection type. Due to the well known squaring effect in these receivers, electrical processing of the output signal y(t) is capable of compensating only a very limited amount of dispersion. See, for example, “Performance of Smart Lightwave Receivers with Linear Equalization” Cartledge et al, J Lightwave Tech, Vol. 10, No. 8, August 1992, pp.1105-1109; and “Electrical Signal Processing Techniques in Long-Haul Fiber-Optic Systems” Winters et al, IEEE Trans. Comms, Vol. 38, No. 9, September 1990, pp. 1439-1453}.
In addition to the squaring effect in conventional receivers, optical modulators also frequently display a non-linear performance characteristic. Nonlinearity compensation of modulators can be implemented in the electrical domain (“Reduction of Dispersion-Induced Distortion in SCM Transmission Systems by using Predistortion-Linearized MQW-EA Modulators”, Iwai et al, J. Lightwave Tech., Vol. 15, No. 2, February 1997, pp. 169-177). It is also possible to provide the nonlinear compensation in the optical domain (“Mitigation of Dispersion-Induced Effects using SOA in Analog Optical Transmission”, Jeon et al, IEEE Photonics Technology Letters, Vol. 14, No 8, August 2002, pp. 1166-1168 and “Predistortion Techniques for Linearization of External Modulators”, Wilson, 1999 Digest of the LEOS Summer Topical Meetings, 1999, pp. IV39-IV40), or via hybrid optical/electrical domains (“Signal Distortion and Noise in AM-SCM Transmission Systems employing the Feedforward Linearized MQW-EA External Modulator”, Iwai et al, J. Lightwave Tech., Vol. 13, No. 8, August 1995, pp. 1606-1612 and U.S. Pat. No. 5,148,503.
While modulator non-linearity can be compensated, the output signal y(t) detected at the Rx end of the communications system contains distortion components due to non-linearities in both the modulator (transmitter) 2 and the receiver 6, as well due to optical dispersion within the link 4. These distortions are compounded, one upon the other, and it is difficult to distinguish distortions of the output signal y(t) due to non-linearity of the modulator 2 or the receiver 6. It is also difficult to distinguish these effects from dispersion.
Accordingly, a cost-effective technique for mitigating the effects of dispersion on high bandwidth optical signals remains highly desirable.
Accordingly, an object of the present invention is to provide a technique for mitigating effects of dispersion on high bandwidth optical signals in an optical communications system.
An aspect of the present invention provides a method of compensating optical dispersion of a communications signal conveyed through an optical communications system. A compensation function is determined that substantially mitigates the chromatic dispersion imparted to the communications signal by the optical communications system. The communications signal is them modulated in the electrical domain using the compensation function.
The method of the invention can be implemented at either the Tx or Rx ends of the communications system, or may be divided between both ends, as desired. In cases where the method of the invention is implemented in the transmitter, the communication signal in the form of an input electrical signal (e.g. a substantially undistorted binary signal) is digitally filtered using the compensation function to generate a predistorted signal. The predistorted signal is then used to modulate an optical source to generate a corresponding predistorted optical signal for transmission through the optical communications system. This arrangement is particularly advantageous, because the predistorted signal can incorporate compensation for dispersion and component non-linearities throughout the system. Consequently, dispersion compensation can be effectively implemented independently of the type of detection (i.e. direct or coherent) used in the receiver.
In cases where the method of the invention is implemented in the receiver, the received optical signal is converted into a corresponding received electrical signal, which includes distortions due to dispersion imparted on the optical signal by the optical communications system. The received electrical signal is then sampled (e.g. using an analog-to-digital converter) and digitally filtered using the compensation function to generate an output electrical signal which is a substantially undistorted version of the original communications signal.
Thus the present invention compensates optical dispersion by digitally filtering a communications signal in the electrical domain. This filtering of the communications signal is governed in accordance with the required compensation function of the communications system transfer function and the non-linearity compensation required. With this arrangement, arbitrary optical dispersion imparted by the communications system can be compensated in such a manner that a comparatively undistorted output signal is generated at the receiving end of the communications system.
Further features and advantages of the present invention will become apparent from the following detailed description, taken in combination with the appended drawings, in which:
It will be noted that throughout the appended drawings, like features are identified by like reference numerals.
The present invention provides a method and system for compensation of chromatic dispersion in an optical communications system.
As shown in
x 1(t)=x(t)conv c(t)
where “conv” is the convolution function.
The predistorted input signal x1(t) 12 is then converted to a corresponding predistorted optical signal X1 OPT(w) by the E/O converter 2 and transmitted through the optical link 4 to the receiver. Within the receiver, the incoming optical signal Y1 OPT(w) is converted by the O/E converter 6 into a corresponding output signal y(t). As may be seen in
The predistorted signal x1(t) 12 can then be converted into the corresponding predistorted optical signal X1 OPT(w) by means of a conventional electrical to optical converter 2. For example, in the illustrated embodiment, electrical to optical conversion is accomplished using a tuned optical source 18 such as a narrow band laser coupled to a conventional optical modulator 20. In this case, the predistorted signal 12 can be used as an input to control the optical modulator 20 in a manner known in the art.
Various methods may be used to derive the compensation function c(t). In the example of
In the foregoing discussion, the optical modulator 24 was assumed to be fully linear, so that the modulator 20 did not introduce any further distortions beyond those accounted for by the system transfer function H(w). Depending on how the system transfer function H(w) is defined, this approach may yield satisfactory results. However, in many cases it may be desirable to treat the transfer function of the optical fiber span 4 separately from that of the optical modulator 2 and the optical-to-electrical converter 6 in the receiver. In this case, the compensation function c(t) calculated above will not account for distortions introduced by the optical modulator 20 or the optical-to-electrical converter 6. However, the performance of these components is typically well characterized. It is therefore possible to implement a non-linear compensator 16 in order to further distort the predistorted signal 12 in such a manner as to fully compensate non-linearities of the optical modulator 20 and/or the O/E converter 6, as desired. The non-linear compensator 16 can be implemented as a nonlinear digital filter, such as an LUT or nonlinear multiplier.
As mentioned above, the digital filter 14 may be implemented in a variety of ways.
As shown in
Because the RAM LUT 26 performs a substantially linear filtering function, it is possible to construct the LUT 26 as a set of two or more Random Access Memory blocks (not shown), if desired. In this case, each RAM block stores a respective portion of the desired numerical value 28 of the predistorted signal component. Thus the outputs generated from each RAM block can be summed, in a conventional manner, to produce the desired numerical value 28. This arrangement allows the LUT 26 to be larger than can conveniently be accommodated within a single RAM block.
Each register of the look-up table 16 contains at least one digital number representing the analog value of the predistorted signal x1(t) 12, which has been previously calculated for a unique set of N bits. Accordingly, as the input serial bit stream is latched through the serial-to-parallel converter 14, a stream of successive digital values 28 of the predistorted signal 12 are output from the look-up table 16. This stream of digital values 28 can then be converted into the corresponding analog predistorted signal x1(t) 12 using a digital-to-analog converter 30. The analog predistorted signal x1(t) 12 can then be converted into the corresponding predistorted optical signal X1 OPT(W) by means of a conventional electrical to optical converter 2, as described above.
Various methods may be used to calculate each of the digital values stored in the look-up table 16. In the example of
Because chromatic dispersion causes a time domain distortion of an input signal, the instantaneous value of the analog predistorted input signal 12 at a particular instant (t) will necessarily be a function of the analog waveform of the input data signal x(t) within a time window that brackets the instant in question. The width of the time window, measured in symbols, will generally be a function of the maximum dispersion (D) for which compensation is to be provided; the bandwidth (B) of the optical signal; and the symbol interval (S) of the optical signal. For example, consider an optical communications system in which the transmitter generates an optical signal having a bandwidth of B nanometers and a symbol interval of S picoseconds/symbol. In this case, the maximum dispersion (D) that can be compensated is given by the equation:
where N is the width of the time window, measured in symbols. It will be appreciated that the selected value of N will limit the maximum dispersion (D) that can be effectively compensated. In general, the value of N will be selected based on the expected maximum dispersion of the optical communications system.
In the example of
Following the discussion above, it will be seen that each value stored in the look-up table 16 can readily be calculated (at 32) by applying the calculated compensation function to each one of the 2N possible N-bit sequences. For each N-bit sequence, the calculated look-up table value would then be stored in the RAM look-up table 16 register that is indexed by the N-bit sequence in question. This process will result in the look-up table 16 being loaded with pre-calculated values of the predistorted signal 12 which will be accessed, in sequence, as successive bits of the input data signal x(t) are latched through the serial-to-parallel converter 14.
In some instances, it may be advantageous to arrange the RAM LUT 26 to output more than one numerical value 18 of the predistorted signal 12 for each symbol of the input signal x(t). This can readily be accomplished by calculating the required numerical values 18 for each N-bit sequence, and storing the resulting set of numerical values in the appropriate register. Consequently, as each bit of the input signal x(t) is latched through the serial-to-parallel converter 28, all of the numerical values calculated for each unique N-bit sequence will be output, in an appropriate sequence, from the RAM LUT 26.
As may be seen in
In the embodiments of
As will be appreciated, the multi-dimensional compensation processor 10 can be implemented using multiple compensation paths to generate the predistorted signal x1(t) 12 in any desired format, such as, for example, polar coordinates. The only limitation here is that a suitable optical modulator 24 must be provided for modulating the appropriate optical components in response to the signal components generated by the multi-dimensional compensation processor 10.
The embodiment(s) of the invention described above is(are) intended to be exemplary only. The scope of the invention is therefore intended to be limited solely by the scope of the appended claims.
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|U.S. Classification||398/147, 398/194, 398/159|
|International Classification||H04B10/155, H04B10/12, H04B10/04, H04B10/00, H04B10/18|
|Cooperative Classification||H04B10/07951, H04B10/6161, H04B10/505, H04B10/07953, H04B10/50597, H04B10/508, H04B10/25137|
|European Classification||H04B10/50597, H04B10/25137, H04B10/508, H04B10/505|
|Oct 3, 2002||AS||Assignment|
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|Apr 9, 2010||AS||Assignment|
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